JPH0398433A - Method of winding coil on armature body - Google Patents

Abstract

PURPOSE: To improve an existing method with no possibility of rejection by executing another winding cycle upon finishing a winding cycle to feed a winding wire through an armature slot and forming another set of coils connected with a coil being connected with an element attached to a commutator segment. CONSTITUTION: A winding wire is connected with one commutator hook and then fed by a set number of turns in the form of a loop penetrating armature slots 101, 115 before being wound around a commutator hook 2a. Subsequently, the winding wire is fed again through armature slots 102, 116 and wound around a commutator hook 3a. Finally, the winding wire is passed from a commutator hook 24a to a commutator hook 1a through armature slots 324 114.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an armature body winding method, which includes a commutator attached to an armature shaft and an attached element. a commutator segment having a
A method of winding a winding on an armature body provided with an armature slot, the winding being fed through the armature slot according to a winding cycle and connected to ancillary elements of a commutator segment in one piece. A set of coils is a method of winding windings around the armature body, where the coils are electrically connected to each other via commutator segments.

Furthermore, the invention relates to an electric machine with a stator and an armature.

PRIOR ART The method described above is known in principle and can be implemented in commercially available winding machines. Such a winding machine is disclosed, for example, in US Pat. No. 3,973,738. Known methods are used to form drum-shaped armature bodies with radial armature slots. Starting from a winding wire wound around the hook-shaped accessory element of the commutator, the windings are distributed over a number of coils. To form the first coil, the winding wire is fed the required number of times through two approximately diametrically located armature slots and finally around another hook-shaped attachment element of the commutator. wrapped. The winding wire is again fed through the two armature slots and wound around another hook-shaped attachment to form a second coil. This last operation is repeated for the required number of spools to be shaped. The two spools are then interconnected through the commutator segments of the commutator by bending and heating the hook-type attachment elements to electrically connect the coil ends to the commutator segments. Two winding wires can be used to reduce the winding time of the known method. the result,
Symmetrical winding is possible, with two coils being formed simultaneously.

The known method is suitable when using thin wound wire, for example copper wound wire with a diameter smaller than 0.50 m. Various applications, e.g. 100 to 200 ■
For electric motors designed for wire voltages of
It is necessary to use copper wound wire with a diameter larger than 6 mm. However, when a thick winding wire is used, the rejection rate increases. That is, after winding, the coil ends contact each other in the commutator attachment element, or the hook-type attachment element is mechanically deformed when pulling and cutting the winding wire that came at the end of the winding work. Because it does.

OBJECT OF THE INVENTION The aim of the invention is to improve the known method in such a way that it widens the field of application without the risk of rejection.

(Means for Solving the Problems) The present invention achieves the above object through a structure having the following features. That is, after completing a winding cycle, at least one other winding cycle is performed, and the winding wire passes through the armature slot already provided on the coil side of the set of coils. feeding through and connected to ancillary elements of commutator segments already connected to the set of coils to form another set of coils electrically connected in parallel with the set of coils; That's true.

The advantage of the armature body winding method according to the invention is that by winding the armature body with a thin winding wire that can be wound without difficulty, relatively thick winding wires are not required for electrical design reasons. It is possible to manufacture armatures.

Furthermore, relatively small dimensions of the commutator can be used.

Furthermore, using the method according to the invention, the filling factor of the armature slots is advantageous. Although the method according to the invention requires slightly more time than known methods, the advantages obtained are greater.

A feature of embodiments according to the invention is that the winding cycles are carried out one after the other and the winding wires are not cut during the transition from one winding cycle to the next.

The advantage of this is that at the start of another winding cycle, the winding wires are connected to the correct accessory elements of the commutator, thus saving work and reducing the overall winding time. .

Another feature of the embodiment is that the winding cycles are performed in the same way. As a result, coils of the same winding type and connected in parallel are fixed.

Another object of the present invention is to provide an electric machine including a stator and an armature manufactured by the armature body winding method according to the present invention. The electric machine has two coil sides of a lmth coil electrically connected via a commutator and at least another set of two coil sides electrically connected via a commutator. A portion is present in each armature slot. Thereby, thermal economy can be easily achieved.

The invention will be explained in more detail below on the basis of exemplary embodiments and with reference to the accompanying drawings, in which: FIG.

EXAMPLE The machine according to the invention shown in FIGS. 1 and 2 is configured as a series electric motor and can be connected to a 100-120 V AC power line. Electric motor has stator coil 5L
It has a stator 50 having a rotor or an armature winding. The armature 52 includes a drum-shaped armature main body 56, an armature shaft 58, and a commutator 60.
It is composed of. A radially oriented armature slot for receiving the coil sides is provided on the armature shaft 58.
The armature body 56 is formed as a laminated core and is attached to the armature body 56. In this example, the number of armature slots is 24, and the armature slots are numbered 101-1.
It is indicated by 24. Armature shaft 58 is mounted on two bearings 62 and 64 and is rotatable about its centerline 58a. Commutator 60 is also attached to armature shaft 58 and has 24 commutator segments l-24. Each of the commutator segments has a hook-shaped accessory element 1, called commutator hook for short.
A 24a is provided.

In this illustrative example, the armature winding is designated as 201-2 in the drawings.
It consists of two sets having 24 generally rectangular coils, designated 24 and 225-248, respectively.

The armature winding provided by the method according to the invention is
This will be explained in more detail with reference to the winding diagram shown in the figure.

As can be inferred from the winding diagram, 0. 40
A winding wire 200 shaped by an insulated copper wire with a diameter of mm is connected to one of the commutator hooks.

In FIG. 3, this is commutator hook 1a. The connection is made by wrapping the wire 200 a few turns around the hook. After the above connection, the winding wire is
Two armature slots, namely armature slots 101 and 1
15 in the form of a loop, which is then wound around the commutator hook 2a.

From this point, the winding wire is again fed through the two armature slots, in this case armature slots 02 and 116, and then wound around the commutator hook 3a.

Feeding the winding wire through the armature slots is repeated 22 times in this example. The winding wire is
In the case of the 24th time, it travels from the commutator hook 24a to the commutator hook 1a via the armature slots 24 and 114. The winding cycle described above is partially and diagrammatically shown in solid lines in FIG.

After carrying out a complete winding cycle as described above, e.g. after forming every 18th winding, i.e. one of the 24 coil sets of coils 201-224, the winding cycle is again completely repeated, i.e. Starting again and terminating at commutator hook 1a, another set of coils 225-248 is formed. Third
In the winding diagram shown, further winding cycles are indicated schematically by dashed lines.

The armature 52 wound by the method according to the present invention comprises the coil 20
1-224 set of two coil sides and coil 225-2
There are 48 pairs of two coil sides in each armature slot 10.
1-124.

Furthermore, the armature 52 is characterized in that one set of coils 1' is always electrically connected in parallel with another set of coils. This results in relatively low displacement resistance of the windings, which is advantageous for motor efficiency.

To reduce the winding time, it is indeed possible to use more than one winding wire. For example, it is possible to use two winding wires connected to different commutator hooks, for example commutator hooks 1a and 13a, respectively, at the beginning of the winding cycle. Thereby, the same 2
Several sets of coils can be shaped simultaneously. It is also possible to wind two or more sets of coils.

However, the invention is not limited to this illustrative embodiment. Machines with different numbers of armature slots and more than one set of coils fall within the scope of the invention, as well as methods with more than one winding cycle.

[Brief explanation of drawings]

1 is a partially longitudinal sectional and partially side elevational view of a part of an electrical machine according to the invention; FIG. 2 is a diagrammatic view of the machine line II--II of FIG. Cross-sectional view; FIG. 3 is a winding diagram of the machine shown in FIG. 1-24... Commutator segment la-24a... Commutator block 50... Stator 5l... Stator coil 52... Armature 56... Drum type armature body 58... Armature shaft 60... Commutators 62, 64... Bearings 101-124... Armature slot 200... Winding wire

Claims (1)

[Claims] 1. A method of winding a winding around an armature body provided with an armature slot, which has a commutator attached to an armature shaft and a commutator segment provided with an accessory element. the windings are fed through the armature slots according to a winding cycle and connected to the accessory elements of the commutator segments to form a set of coils, the coils being connected to the commutator segments; A method of winding windings on an armature body electrically connected to each other via segments, wherein after completing said winding cycle, at least one other winding cycle is performed; A line wire is fed through an armature slot already provided on the coil side of said set of coils and connected to an accessory element of a commutator segment already connected to said set of coils. A method for winding an armature body, comprising forming another set of coils electrically connected in parallel with one set of coils. 2. The winding cycles are performed one after another, and the winding wire is not cut when transitioning from one winding cycle to the next. armature body winding method. 3. The armature body winding method according to claim 1 or 2, characterized in that the winding cycles are performed in the same manner. 4. Two coil sides of a first set of coils electrically connected via a commutator, and two coil sides of at least another set electrically connected via said commutator. is present in each armature slot, comprising a stator and an armature manufactured by the armature body winding method according to any one of claims 1 to 3. electrical machine.